Tag Archives: food fraud

Susanne Kuehne, Decernis
Food Fraud Quick Bites

Natural Goes Methodical

By Susanne Kuehne
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Susanne Kuehne, Decernis
Food fraud
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne

The popularity of “natural” foods with consumers has increased exponentially over the past decade or two. While the term “natural” on a food label is not formally regulated by the FDA, “natural flavors” have been defined in the Code of Federal Regulations Title 21 as flavoring constituents derived from a naturally occurring source, such as spice, fruit, vegetable, herb, leaf and more. “Natural” flavors/aromas have specific spectroscopic fingerprints versus synthetically produced volatile organic compounds. This method combines gas chromatography and isotope ratio mass spectroscopy (GC-C-IRMS) to determine whether a fruit aroma is naturally or synthetically-derived, and can be used to build a database of natural flavors.

Resource

  1. Strojnik, L., et al. (July 5, 2021). “Construction of IsoVoc Database for the Authentication of Natural Flavours”. MDPI Open Access Journals.
Susanne Kuehne, Decernis
Food Fraud Quick Bites

Crisp, But Not Clean

By Susanne Kuehne
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Susanne Kuehne, Decernis
Palm Oil, Food Fraud
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne

An especially perfidious type of edible oil fraud is the dissolution of inedible plastic material, such as polypropylene or polyethylene packaging material, in hot cooking oil during the frying process. This is supposed to prolong the shelf life and the crispness of deep-fried snack food, not surprisingly with serious health implications. Attenuated total reflectance fourier-transform infrared spectroscopy (ATR-FTIR) in combination with principal component analysis (PCA) provides a straightforward method to analyze samples directly with minimal preparation, to detect polymers in palm cooking oil, as done in this study.

Resource

  1. Ismail, D. et al. (2021). “Classification Model for Detection and Discrimination of inedible Plastic adulterated Palm Cooking Oil using ATR-FTIR Spectroscopy combined with Principal Component Analysis”. Vol 25 No 3. Malaysian Journal of Analytical Sciences (MJAS).
Susanne Kuehne, Decernis
Food Fraud Quick Bites

Juicy Fraud Case Revealed

By Susanne Kuehne
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Susanne Kuehne, Decernis
Orange slice, food fraud
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne

“Carbon Content of the C3 Cycle” is the method of choice used by the laboratories of the Ministry of Agriculture, Livestock and Supply in Brazil to identify exogenous sugar in juices. In a recent operation, 173,000 liters of juices and coconut water adulterated with 30% added sugars and water were discovered. The fraudulent products were seized and rendered unusable, and large fines are awaiting the offenders. The C3 photosynthetic cycle method has traditionally been used to detect added sugars in the winemaking process.

Resource

  1. Ministério da Agricultura, Pecuária e Abastecimento. (July 30, 2021). “Ação de fiscalização do Mapa apreende 173 mil litros de bebidas com indícios de fraude”.
Susanne Kuehne, Decernis
Food Fraud Quick Bites

Plant A Seed For Real Pomegranate

By Susanne Kuehne
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Susanne Kuehne, Decernis
Pomegranate
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne

The Botanical Adulterants Prevention Program published a bulletin on the adulteration of pomegranate, with descriptions on methods on adulteration detection. Pomegranate fruit, juice, bark, extract and oil from seeds is believed to have anti-inflammatory, antiviral, antioxidant and even anti-tumor properties, and more. Over the past two decades, increasing demand for pomegranate products has instigated a wave of fraudulent activities. Added polyphenols, anthocyanins, sugar, other juices, water and ellagic acid are used as adulterants.

Resource

  1. Cardellina, J.H. and Gafner, S. (August 24, 2021). “Adulteration of Pomegranate Ingredients and Products”. Botanical Adulterants Prevention Program.
Anthony Macherone, Agilent
FST Soapbox

The Link Between Exposure to Xenobiotic Pesticides and Declining Honeybee Colonies and Honey

By Anthony Macherone, Ph.D.
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Anthony Macherone, Agilent

According to data from the Bee Informed Partnership, a national collaboration of leading research labs and universities in agricultural science, managed honeybee populations declined by nearly 40% between Oct. 1, 2018 and April 1, 2019. This is a 7% greater decline compared to the same timeframe during the previous winter.1

Scientists are examining different environmental factors such as the increased use of pesticides and the use of chemicals in agriculture as causes for the rapid decline in global honeybee numbers.

Recent research conducted by my team and I revealed a potentially key reason for the decline in honeybee populations as a result of Nosema ceranae (N. ceranae), a prevalent infection in adult honeybee populations. My team established a link between N. ceranae-infected honeybee colonies and changes in pheromone levels, which in turn, may have a social impact on communication in honeybee colonies.

Moreover, the significant decline in the global honeybee population is likely to be driving an increase in fraudulent honey, meaning that both governments and regulators need to invest in the latest technology to test honey products for authenticity, nutritional values and safety.

The Significance of Honey in Our Global Diet and the Problem at Hand

Honey has been a part of our diet for the past 8,000 years, and with numerous health benefits in addition to having a favorable taste, it is one of the most popular foods across the globe.2

Honeybees produce honey from the nectar of flowering plants, and they are considered a “keystone species” since one-third of human food supply depends on pollination by honeybees.3The species is responsible for pollinating numerous fruit, nut, vegetable and field crops such as apples, almonds, onions and cotton.

The increase of pesticides and chemicals in the environment has been cited as a reason for the decline in bee populations, which has occurred in Western European countries such as France, Belgium, Germany, the UK, Italy, Spain, and the Netherlands, as well as countries such as the United States, Russia and Brazil.4 In fact, the number of honeybee colonies in Europe fell by an average of 16 per cent over the winter of 2017–2018, according to findings published in the Journal of Apiculture Research.5

Global pesticide usage was predicted to increase to 3.5 million tons globally in 2020, which could mean that honeybee populations will continue to diminish at an exponential rate due to the increased use of pesticides.6

The Impact of Pesticides on Global Honeybee Populations

In 2019, a research project was initiated to explore the link between exposure to xenobiotic pesticides and increasing susceptibility to the N. ceranae infection in honeybee colonies, one of the most common infections in adult honeybee populations. The findings suggested that it is not the amount of pesticide exposure, nor a particular kind of pesticide exposure, but rather the number of exposure events from different xenobiotics that is associated with N. ceranae, which infected hives, thereby causing them to diminish.7

For discovery-based (non-targeted) exposome profiling of honeybee extracts, a gas chromatography/quadrupole time-of-flight mass spectrometer (GC/Q-TOF) was used. Additionally, spectral library searches and compound annotation were performed using the NIST 14, RTL Pesticides and the Fiehn Metabolomics libraries to provide efficient and timely research outputs.8

Expanding on this research further in 2021, a scientist’s team established a link between N. ceranae-infected honeybee colonies and changes in pheromone levels, which showed a potential impact on social communication in honeybee colonies. While it was concluded that further analysis is required, as research points to the real possibility that N. ceranae-infected honeybee colonies show increased alarm pheromones and may affect hive communication, which could ultimately, be a reason for the collapse of colonies.9

As N. ceranae is causing honeybee populations to dwindle worldwide, the decline in ‘real’ honey supplies is correspondent with an increase in ‘fake’ honey. Inauthentic honey products cause businesses and consumers to lose out, as ‘fake’ honey floods the market and makes producing ‘real’ honey more expensive.

Growth in Fake Honey

The global honey market has grown from 1.5 million tons produced annually in 2007 to more than 1.9 million tons in 2019 and the market is estimated to be worth $7 billion, however the decline in bee populations has led to an increase in honey adulteration to fill the global demand for honey.10

Declining supplies of authentic honey combined with the strong consumer demand for honey has driven significant adulteration of this product. Honey is considered to be one of the most adulterated foods after milk and olive oil, with every seventh jar of honey opened daily around the globe thought to be fake.11, 12 Consequently, legitimate honeybee keepers and business owners are forced to slash costs, which is problematic for those who depend on selling authentic honey.

To put into perspective the scale of the issue, the European agricultural organization, Copa-Cogeca noted that most honey imported from China into Europe is mixed with syrup.13 In 2018, the Honey Authenticity Project in Mexico commissioned tests for British supermarket honey products, and 10 out of 11 products failed the tests due to suspected sugar adulteration.14

While in the United States, it was recently reported that thousands of commercial beekeepers have taken legal action against the country’s largest honey importers and packers for allegedly flooding the market with hundreds of thousands of tons of “fake” honey.15 Furthermore, a recent workshop led by the South Africa Bee Industry Organization (SABIO) also conducted research on the impact of fraudulent honey, and the organization found that honey imports into South Africa have tripled to 6,000 tons a year, 60% of which come from China.16 As the demand for honey products stays robust but authentic honey supplies dwindle, the issue of counterfeit honey will continue to worsen.

Testing Methods to Identify Authentication

The issue of fraudulent food products like honey has driven governments to set up laws and departments dedicated to food integrity. Examples include FSMA, the UK National Food Crime Unit, Chinese Food Safety Law, and European Commission Food Integrity Project.

Food retailers often have contractual agreements with suppliers that require them to carry out authenticity testing of their ingredients, which can be carried out by third-party laboratories.17 Food adulteration can be identified via targeted and non-targeted testing and common testing methods include molecular spectroscopy solutions for ‘in the field’ screening and more in-depth laboratory analysis to determine quantities of ingredients.

Analytical instrument manufacturers have been working closely with governments to provide the latest methods to test the authenticity of honey products, as well as working with the Association of Official Agricultural Chemists (AOAC) on the development of both targeted and non-targeted standards for authenticity testing in milk, honey and olive oil.
Measuring contaminants is a key solution to identifying counterfeit honey and gas chromatographs are able to analyze and quantify the absence or presence of hundreds of pesticides in organic-labeled honey.18

Testing and analysis can be done using a range of analytical instrumentation such as solid phase microextraction followed by gas chromatography/mass spectrometry (SPME-GC/MS), inductively coupled plasma-mass spectrometry (ICP-MS), and gas/liquid chromatography/quadrupole time-of-flight (GC/Q-TOF and LC/Q-TOF). These instruments can be coupled with innovative software solutions for advanced data analysis.19

Future Research Must Continue

The spread of diseases such as N. ceranae, which have been shown to be aggravated by human-induced environmental factors, are decimating global honeybee populations, which in turn is negatively impacting ecosystems and humans, and the availability of authentic honey. This demise in authentic honey supplies is additionally fueling a rise in fake honey products, where consumers are misled into buying counterfeit honey.

Future research must continue to seek associations with environmental exposures effects on biological pathways and adverse health outcomes in honeybee populations, and in fact, novel environmental exposures have been found to be associated with seven of the top diseases known to affect honeybees. These putative associations must be validated with targeted follow-up studies to determine if they are causative factors in the decline of honeybee populations. If proven to be causative, scientists and policy makers can work together to mitigate these factors and hopefully reverse the global trend of honeybee colony decline.

References

  1. Loss & Management Survey, Bee Informed. Last accessed: June 2021
  2. Agilent.‘The Buzz around Fake Honey’. 2018. Last accessed: June 2021
  3. University of California – Berkeley. ‘Pollinators Help One-third Of The World’s Food Crop Production’. 2006. Last accessed: June 2021
  4. European Parliament. ‘What’s behind the decline in bees and other pollinators?’. 2021. Last accessed: June 2021
  5. Journal of Apiculture Research. ‘Loss rates of honeybee colonies during winter 2017/18 in 36 countries participating in the COLOSS survey, including effects of forage sources’. 2019. Last accessed: June 2021
  6. SN Applied Sciences. ‘Worldwide pesticide usage and its impacts on ecosystem’. 2019. Last accessed: June 2021
  7. PLOS ONE. ‘Honey bee (Apis mellifera) exposomes and dysregulated metabolic pathways associated with Nosema ceranae infection’. 2019. Last accessed: June 2021
  8. PLOS ONE. ‘Honey bee (Apis mellifera) exposomes and dysregulated metabolic pathways associated with Nosema ceranae infection’. 2019. Last accessed: June 2021.
  9. Royal Society Open Science. ‘Increased alarm pheromone component is associated with Nosema ceranae infected honeybee colonies’. 2021. Last accessed: June 2021
  10. Statista. ‘Global market value of honey 2019-2027’. 2021. Last accessed: June 2021
  11. Insider.com. ‘Honey is one of the most faked foods in the world, and the US government isn’t doing much to fix it.’ 2020. Last accessed: June 2021
  12. Dow Jones. ‘Hi honey. I’m not from home.’ Last accessed: June 2021
  13. Apiservices.biz. ‘Copa-Cogeca Position Paper on the European Honey Market.’ February 2020. Available at: Copa-Cogeca position paper on the European honey market (apiservices.biz)
  14.  WIRED. ‘The honey detectives are closing in on China’s shady syrup swindlers’. 2021. Last accessed: June 2021
  15.  The Guardian. ‘US beekeepers sue over imports of Asian fake honey’. 2021. Last accessed: June 2021
  16.  Times Live. ‘Falsely labelled, mixed with syrup or ‘laundered’: Honey fraud is rife in SA’. 2021. Last accessed: June 2021.
  17.  UK Parliament Post. Postnote, number 624. ‘Food Fraud’. Last accessed: June 2021
  18. Agilent. ‘The Health Benefits of Honey’. 2017. Last accessed: June 2021
  19. Agilent. ‘Protecting our honey against food adulteration’. Last accessed: June 2021.

 

Susanne Kuehne, Decernis
Food Fraud Quick Bites

Today’s Pig Is Tomorrow’s…Beef?

By Susanne Kuehne
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Susanne Kuehne, Decernis
Pig, cow, food fraud
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne

Balkan countries are enduring their share of adulterated foods. In Kosovo, commercial samples of meat labelled as beef or chicken were investigated with ELISA (enzyme-linked immunoassay test) and PCR (polymerase chain reaction) in order to detect pork mitochondrial DNA. The test series looked into the efficiency and cost of different methods and showed a preference for commercial ELISA combined with real-time PCR. Almost a third of beef was adulterated with pork, as were 8% of the chicken samples.

Resource

  1. Gecaj, R.M., et al. (August 2021). “Investigation of pork meat in chicken and beef based commercial products by ELISA and real-time PCR sold at retail in Kosovo”. Czech Academy of Agricultural Science, Open Access CAAS Agricultural Journals.
Karen Everstine, Decernis
Food Fraud Quick Bites

Why Is Honey Fraud Such a Problem?

By Karen Everstine, Ph.D., Gina Clapper, Norberto Luis Garcia
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Karen Everstine, Decernis

Honey is a deceptively simple product. According to Codex Alimentarius, it is the “natural sweet substance produced by honey bees from the nectar of plants or from secretions of living parts of plants or excretions of plant sucking insects on the living parts of plants, which the bees collect, transform by combining with specific substances of their own, deposit, dehydrate, store and leave in the honey comb to ripen and mature.” The result of this extensive process is a substance that consists primarily of fructose and glucose and, therefore, is prone to adulteration with sugars from other sources. Unlike sugars from other sources, honey contains a variety of vitamins, minerals, amino acids, enzymes, and other micronutrients, which makes it uniquely valuable.1

Honey is much more expensive to produce than other sugar syrups, particularly those from plants such as corn, rice, sugarcane and sugar beets. As a result, there is a strong economic advantage for replacement of honey with other sugar syrups. Honey consistently rates as one of the top five fraudulent food products based on public sources of data (see Figure 1).

Food Fraud Records
Source: Decernis Food Fraud Database

Testing to ensure honey authenticity is not always straightforward.2 Traditionally, analytical methods could detect C4 sugars (from corn or sugarcane) but not C3 sugars (from rice, wheat or sugar beets). Testing methods have evolved, but there are still many challenges inherent in authenticating a sample of a product labeled as “honey.” One promising area of authentication is based on nuclear magnetic resonance (NMR) spectroscopy, which is a method that can identify and quantify a large number of substances in a sample. Instead of trying to detect one particular adulterant, this method allows comparison of the results of a sample to a range of verified honey samples for authentication (similar to “fingerprinting”). This makes it a flexible and more powerful method for authentication. However, one of the current challenges with NMR is that large databases of verified results must be built to enable effective fingerprinting of any single honey sample. Given the variety of botanical sources of nectar, geographic locations of honey productions, and various other natural factors, this is a large task.

USP FCC, along with their global network of scientific experts, has two ongoing projects related to honey authenticity. The first is development of a honey identity standard. The purpose of the standard is to provide a set of specifications and methods that can be used to help ensure a product—particularly one with natural variability, such as a juice, cold-pressed oil or honey—is accurately and appropriately represented. The standard is voluntary and intended for use in business-to-business relationships (it is not regulatory in nature). It is flexible enough to allow for the natural variability of the product. The FCC honey standard was posted and available for public comment last year and is anticipated to be published in the Food Chemicals Codex in September 2021. The USP Honey Expert Panel is also developing a food fraud mitigation guidance document specific to honey. The guidance will include a detailed description of the various contributing factors to honey fraud and guidance on developing a fraud mitigation plan specific to honey. It is planned for inclusion in the FCC Forum in 2022.

Honey is incredibly popular as a food and food ingredient, and honeybees are a critical resource for agriculture and ecological health. Therefore, prevention of honey fraud is a particularly important issue for both the food industry and consumers.

References

  1. Ajibola, A., et al. (June 20, 2012). “Nutraceutical values of natural honey and its contribution to human health and wealth”. Nutr Metab.
  2. Garcia, N. and Schwarzinger, S. (2021). “Food Fraud: A Global Threat With Public Health and Economic Consequences”. Chapter 15 – Honey Fraud. P. 309-334.
Susanne Kuehne, Decernis
Food Fraud Quick Bites

Don’t Open That Sesame

By Susanne Kuehne
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Susanne Kuehne, Decernis

Sesame oil is a popular edible oil in China, with fraudulent sesame oil on the rise. The Chinese government released new guidelines to protect consumers from sesame oil fraud. Consumers are strongly advised to carefully check the nutrition label, purchase from reliable sources and not from unauthorized small vendors, be cautious when purchasing sesame oil online, and investigate the oil’s properties such as color and smell.

Sesame plant
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne

Resource

  1. Neo, P. (August 23, 2021) “Food oil fraud: China issues warning about adulterated and blended sesame oils”. Food Navigator-Asia.
Susanne Kuehne, Decernis
Food Fraud Quick Bites

Sergeant Pepper On Duty

By Susanne Kuehne
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Susanne Kuehne, Decernis
Pepper, food fraud
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne

A Northern Ireland-based analytical lab added white pepper to its portfolio of food authenticity tests based on spectroscopy with chemometric analysis. White pepper, the ripe berries of the piper nigrum plant, is undergoing an additional production step, fetches a higher price than black pepper and therefore is a target for fraudsters. Often, bulking substances like skins, flour, husks and spent materials are used, but in some cases of pepper fraud, the substances used were hazardous to human health.

Resource

  1. Taylor, P. (August 24, 2021). “With white pepper fraud on the up, Bia unveils authenticity test”. Securing Industry.
Susanne Kuehne, Decernis
Food Fraud Quick Bites

If Fish Could Talk

By Susanne Kuehne
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Susanne Kuehne, Decernis
Seafood fraud
Find records of fraud such as those discussed in this column and more in the Food Fraud Database, owned and operated by Decernis, a Food Safety Tech advertiser. Image credit: Susanne Kuehne.

Seafood fraud is still on an almost unchanged high level in Canada. Based on a 2021 investigation by Oceana Canada, 46% of 94 DNA tested seafood samples were not what the label claimed them to be. The Oceana report describes seafood traceability in Canada, the 2021 seafood fraud investigation and results, what consumers can do, and suggestions for the federal government on how to mitigate seafood fraud. These recommendations include setting up a traceability system, labeling standards, improving testing standards and better documentation in the supply chain.

Resource

  1. Oceana. (August 2021). “Seafood Fraud in Canada: 2021 Testing Results Report”.